DE2511800C3 - Microwave filters with cavity resonators operated in dual mode and additional overcouplings - Google Patents

Description

The invention relates to a filter for very short electromagnetic waves, consisting of several

'5 coupled together, operated in dual mode Cavity resonators, of which the first and last resonator with connecting lines for the feed or the decrease in electromagnetic energy are provided and in which between at least two resonators which are not directly consecutive in their electrical mode of operation, an additional one Coupling is provided and the individual resonators in adjacent ones running parallel to one another Rows are arranged.

As is known, filters in microwave technology are made up of several microwave resonators coupled to one another constructed whose coupling can be either capacitive or inductive. The resonators themselves can for example consist of so-called coaxial line resonators or consist of waveguide resonators.

In contrast to the filters built with concentrated switching elements, due to the geometrically fixed, predetermined configuration of the resonators not each in concentrated technology realizable circuit easily transferred to the frequency range of microwaves. This difficulty occurs in particular when it is necessary, in the attenuation characteristics of the filter attenuation poles

«O and / or a transit time flattening in the pass band of the filter by generating additional couplings of filter circuits and is remedied by the in the German Offenlegungsschrift 19 42 867 specified arrangement of the resonators in adjacent rows with

* 5 additional cross couplings in the common Partition wall of two resonators each, arranged in different rows.

The possibility of constructing microwave filters with cavity resonators is also known can be operated in more than one mode at the same time. ("Microwave Filters Employing a Single Cavity Excited in More than One Mode, "Journal of Applied Physics," Vol.22, No. 8, August 1951, pages 989-1001 of Wei-Guan Lin; "A Four Cacity Elliptic Waveguide Filter", "IEEE Transactions on Microwave Theory and Techniques ", Vol.-MTT. 18, No. 12, pages 1109-1114, December 1970 by Williams, A. E.) Preferably two identical, but orthogonal modes are used in Hioi or Hm resonators and through a coupling screw attached at 45 ° to the direction of the E-vectors is coupled to one another (Dual mode). This allows two electrical resonant circuits of a filter in a single cavity resonator can be realized in a technically sensible way. Because of the weight savings that can be achieved with dual-mode operation and volume up to 50% results in an important field of application, especially in satellite technology, especially because of the high filters used there

electrical requirements are made, which translates into a relatively large number of electrical Oscillating circles expresses.

Since these filters also have damping levels and / or A leveling of the transit time in the pass band are required, the desire is to find suitable ones for this Find filter circuits in dual-mode technology. In a realization proposal has already been made in this context (»Nonminimum Phase Optimum Amplitude Bandpass Waveguide Filters ","! EEE Transactions on Microwave Theory and Techniques ", Vol. MTT-22, No. 4, April 1974 from Atia, A. E. and Williams, A.E), which is however limited to filter circuits, which are symmetrical in structure as well as in elemental values, which also often overlapping, not preselectable according to number and geometric position within the filter arrangement have additional couplings and their number of electrical oscillating circuits is a multiple of 4 must be, so this is often not to be implemented in practice

From the essay »Narrow Bandpass Waveguide Filters« by E A tia and E. Williams (IEEE Transactions on Microwave Theory and Techniques, Vol. MTT-20, No. 4, April 1972, pages 258-265) furthermore, in particular from page 261, left column, a reference to the possibility of expanding there specified dual-mode filter structures by connecting a further resonator are known, however are based on the calculation bases for the switching Jo winnung in this essay consistently on symmetrical matrix structures, so that in the implementation always non-canonical circuits with not preselectable with regard to their position and therefore multiple crossing additional overcouplings are obtained.

The invention is based on the object of providing asymmetrical, dual mode according to element values specify operating filter circuits whose number of electrical oscillating circuits is a multiple of 2 * o amounts and targeted in their position within the filter arrangement and in their sign preselectable and realizable in their value cross-coupling of corresponding filter circuits is possible are. «

Starting from a filter for very short electromagnetic waves, consisting of several together coupled cavity resonators operated in dual mode, of which the first and last resonator with connecting lines for the feed or the decrease in electromagnetic energy are provided and in which between at least two in the electrical mode of operation not directly successive resonators an additional Coupling is provided and the individual resonators in adjacent ones running parallel to one another Lines are arranged, this object is achieved according to the invention in that the additional couplings are arranged without crossing, and thereby the number of resonators in at least one row is different from the number of resonators in the other rows.

A particular advantage of the invention is that the necessary in the known prior art Restrictions on the circuit structure are eliminated and the number of im Dual-mode realizable filter circuits significantly enlarged.

A particular advantage over the state of Technology is given by the fact that the coupling organs or the organs for additional overcoupling already are preselectable in the filter design with regard to their arrangement within the filter arrangement, and that generally always result in executable filter arrangements.

Due to the possibility of filter circuits, their additional couplings do not overlap many times are to be realized, there is also the advantage that these additional couplings are at least partially assume values that can be better realized, and that also improves the tunability of the filter and the sensitivity to mismatch is reduced.

The invention is explained in more detail below with the aid of exemplary embodiments. It shows in the drawing

Fig. 1 shows a fourteen-circuit filter circuit with four additional cross-coupling,

F i g. 2 shows a first filter arrangement according to the invention of the circuit according to FIG. 1,

3 shows a second filter arrangement according to the invention,

4 shows a technically possible embodiment of a filter according to FIG. 3,

F i g. 5 dai the electrical equivalent circuit diagram of a filter according to FIG. 3,

F i g. 6 a third filter arrangement according to the invention (Cauer bandpass),

F i g. 7 shows the electrical equivalent circuit diagram of a filter according to FIG. 6th

In Fig. 1 is a fourteen-circuit filter circuit which is asymmetrical in terms of structure and rating values and has four additional cross-couplings as an electrical equivalent circuit diagram of the arrangement according to FIG. 2 shown. It is a four-pole circuit, in whose shunt branches the parallel resonant circuits 51 to 514 are located and whose coupling takes place via the coupling inductances 1/2, 2/3, 3/4 ... 13/14 located in the series branch. As an additional coupling there is a coupling inductance 4/13 between the parallel resonant circuits 54 and 513, between the parallel resonant circuits 55 and 512 a coupling inductance 5/12, between the parallel resonant circuits 56 and 511 a coupling inductance 6/11 and between the parallel resonant circuits 57 and 510 a coupling inductance 7 / 10 introduced.

In the embodiment according to FIG. 2 shows a filter arrangement according to the invention consisting of seven cavity resonators 1 to 7, the physical equivalent circuit of which is represented by the circuit of FIG. 1 is given The resonators 1 to 7 are distributed on two superimposed rows A and B in such a way that row A contains the resonators 1 to 4, row B contains the resonators 5 to 7, and that those in both rows are adjacent or on top of each other Resonators each have a common partition. In the present case, the adjacent resonators 1 and 2, 2 and 3, 3 and 4 of row A, the adjacent resonators 5 and 6, 6 and 7 of the line Bund have the superimposed resonators 2 and 7, 3 and 6 and 4 and 5 respectively a common partition. The coupling elements for coupling the resonators operated in Du?! Mode are designed as slotted coupling blades and are arranged in such a way that the electrical energy supplied to resonator 1 of the filter passes through resonators 1 to 4 of line A and 5 to 7 of line £ one after the other .

25 W 800

In the exemplary embodiment, two adjacent parallel resonant circuits are shown in the equivalent circuit diagram Fig. 1 by one each, like all used here Realized resonators in dual mode with two orthogonal modes operated resonator. The the E-vectors assigned to individual modes are accordingly within a resonator also uiihogonal and in the figure corresponding to the associated parallel resonant circuits 51 to S14 with £ 1 and denoted to £ 14. The parallel resonant circuits 51 and 52, through the resonator 2 the parallel resonant circuits S3 and 54 and correspondingly through the resonators 3 to 7 the parallel resonant circuits 55 to 514 are implemented.

Each of the resonators has a coupling screw K 1/2 to K 13/14 arranged at an angle of 45 ° between the associated E vector Ei, E 2 to £ 13, £ 14 for setting the coupling between the orthogonal modes operated in it Mistake. By means of these coupling screws, the coupling inductivity between two adjacent parallel resonant circuits implemented in a resonator of the equivalent circuit according to FIG. 1 realized. For tuning, each resonator is also provided with tuning screws on two orthogonal outer walls, for example the resonator 1 with the tuning screws A 1 and A 2 for the modes assigned to the parallel resonant circuits 51 and 52. The tuning screws attached in the same way to the remaining resonators 2 to 7 are not shown for the sake of clarity.

In the embodiment according to FIG. 2, the coupling elements are designed as slot couplings, which can optionally also, at least partially, be replaced by hole couplings, and the coupling of resonator 1 to resonator 2 or the mode corresponding to the parallel oscillation 52 and having the E vector £ 2 takes place on the The modes corresponding to the parallel resonant circuit 53 and having the E vector £ 3 through the coupling slot CS2 / 3 arranged in the common partition of the resonator 1 and 2 perpendicular to the E vectors £ 2 and £ 3. The coupling of resonator 2 to the adjacent resonator 3 or its associated modes with the E vectors £ 4 and £ 5 takes place via the coupling slot CS 4 arranged in the common partition of these resonators perpendicular to the £ vectors £ 4 and £ 5 / 5.

Exactly the same considerations regarding the arrangement of the coupling slots also apply to the following resonators 4 to 7 with the associated E vectors £ 7 to £ 14, the coupling slot provided for coupling the wave modes with the associated E vectors £ 6 and £ 7 CS 6/7 in the common partition of the resonators 3 and 4, the coupling slot CS 8/9 in the common partition of the resonators 4 and 5, which is provided for the coupling of the wave modes with the associated £ -vectors £ 8 and £ 9, which is for the coupling of the wave modes with the corresponding E- vectors £ 10 and £ 11 provided coupling slot CS 10/11 in the common partition wall of the resonators 5 and 6 and the £ 12 and £ 13 provided for the coupling of the wave modes with the corresponding E- vectors coupling slot CS 12/13 is arranged in the common partition wall of the resonators 6 and 7

In the partition common to the resonators 2 and 7, an additional coupling slot CS4 / 13 is made perpendicular to the F-vectors £ 4 and £ 13, which corresponds to the coupling slot 4/13 of the circuit according to FIG. More additional coupling ?! ' CS 5/12, C56 / 11 and C57 / 10 are in the common partitions of the resonators 3 and 6,3 and 6 as well as 4 and 5 perpendicular to the E-vectors £ 5 and £ 12, £ 6 and £ 11 and £ 7 unJ £ 10 and correspond to the additional overcoupling inductances 5/12, 6/11 and 7/10 of the equivalent circuit diagram according to Fig. 1.

The additional magnetic couplings can be correctly calibrated through the spatial allocation of the Dna! -Mode coupling screws can be implemented for two resonators in the counting mode (positive inductive or negative inductive), for example when an electrical Coupling is not possible because the electrical ii vectors run parallel to the common partition.

In Fig. 3 schematically shows a further Fiitcranordnung according to the invention, the dual-mode Hioi cavity resonators 1 to 7 of which are arranged in three superimposed rows A, B and C so that the superimposed in adjacent rows and the adjacent resonators each have a common partition. In row A the resonators 1 and 2, in row B the resonators 5, 4 and 3 and in row C the resonators 6 and 7 are arranged side by side in such a way that the resonators 1 and 4, 2 and 3, 5 and 6 as well as 4 and 7 each lie one above the other and have a common partition.

This filter arrangement is of little technical importance, however, since the resonator 4 is not of two orthogonal sides are accessible for the attachment of tuning screws.

In Fig. Figure 4 is an improved embodiment of the filter of Figure 4. 3 shown schematically, whose resonator rows A, B and C are not as in the case of the FIGS. 3 run in one plane, but partially in orthogonal planes, which ensures that all resonators are accessible for tuning from two orthogonal sides.

In this filter arrangement, lines A and B are identical to those in FIG. 3 so that the resonators 1 to 5 are identical in their mutual arrangement to that in FIG. 3 are. The line C formed by the resonators 6 and 7 is in this embodiment not arranged below, but next to the line B , whereby the resonators 5 and

so 6 as well as 4 and 7 not as in F i g. 3 lie on top of each other, but lie next to each other and each have a common Have partition and the resonator 4 as well as the other resonators for attaching the Voting organs are accessible from two orthogonal sides

In Fig. 5 is the physical equivalent circuit diagram of the filter arrangements according to FIGS. 3 and 4 shown. It shows a structurally symmetrical four-pole circuit, which, however, is asymmetrical with regard to the element values and in whose shunt branches the parallel resonance circuits 51 to 514 are located, the coupling of which is in each case via the im Inductivities 1/2, 2/3 ... 13/14 lying in series branch is also carried out, the parallel resonance circuits 52 and 57 via an inductance 2/7, the parallel resonance circuits 53 and 56 via an inductance 3/6, the parallel resonance circuits 58 and 513 via an inductance 8/13 and the parallel resonance circuits 59 and 512 with one another via a further inductance 9/12

coupled.

The parallel resonant circuits 51 and 52 of the equivalent circuit diagram are due to the resonators 1 of the exemplary embodiment according to FIGS. 3 and 4 realized, the parallel oscillation circuits 53 and 54 through the resonators 2 and so on up to the parallel oscillation crises 513 and 514, which are implemented by the resonators 7.

in Fig.6 is another embodiment of a Filter according to the invention shown schematically. It is made up of the three Hioi resonators 1 to 3, of which the resonators 1 and 2 are combined into a row and the resonator 3 next to this Row is arranged and has a common partition wall with the resonator 1.

The equivalent circuit diagram of this filter arrangement in which

it is a Cauer bandpass filter with regard to its structure and its element values asymmetrical four-pole connection of the F i g. 7 shown, in whose shunt branches the parallel resonance circuits 51 to 56, the coupling of which via the inductances 1/2, 2/3, 3/4, 4/5 lying in the series branch and 5/6 takes place. In addition, the parallel resonance circuit 51 is connected to the parallel resonance circuit via a capacitance 1/4 54 and coupled to the parallel resonance circuit 56 via the inductance 1/6. The parallel resonance circuits 51 and 54 are in the associated embodiment according to FIG. 6 through the resonator 1, the parallel resonance circuits 52 and 53 through the resonator 2 and the parallel resonance circuits 55 and 56 realized by the resonator 3.

For this purpose 2 sheets of drawings

Claims (11)

Patent claims: 1. Filter for very short electromagnetic waves, consisting of several interconnected, dual-mode operated cavity resonators, of which the first and last resonator are provided with connecting lines for the supply and removal of electromagnetic energy and between at least two In the electrical mode of operation, an additional coupling is provided for resonators not directly following one another and the individual resonators are arranged in adjacent rows running parallel to one another, characterized in that the additional couplings (4/13, 5/12, 6/11, 7 / OK) ütwrkreu-ZL'ngsfrei are arranged, and that as a result, the number of resonators (5, 6, 7) in at least one row (B) is different from the number of resonators (1,2,3,4) in the other rows ( A). 2. Filter according to claim 1, characterized in that the total number of resonators (1 to 7) is odd 3. Filter according to claim 1 and 2, characterized in that each resonator (1 to 7) for Coordination of at least two orthogonal outer walls is accessible. 4. Filter according to claims 1 to 3, characterized in that at least two superimposed lines (A and B) and at least two, from one of the superimposed lines (z. B. B) and at least one further line (C) formed, adjacent Lines (B and C) are provided (Fig. 4). 5. Filter according to claims 1 to 4, characterized in that the sign of additional inductive couplings is given by the mutual spatial arrangement of coupling screws (K 1/2; K 3/4) of two consecutive resonators in the counting mode. 6. Filter according to claims 1 to 5, characterized in that some of the couplings as inductive and the rest are designed as capacitive couplings. 7. Filter according to Claims 1 to 5, characterized in that the organs (CS2 / 3; CS 4/13) provided for coupling and for additional coupling of the resonators (1 to 7) are designed as inductively acting couplings. 8. Filter according to claims 1 to 5, characterized in that the for coupling the resonators (1 to 7) provided organs as inductively acting couplings and the additional couplings are alternately designed as capacitively and inductively acting couplings. 9. Filter according to claims 1 to 5, characterized in that the for coupling the resonators (1 to 7) provided organs as capacitive couplings and the additional couplings are alternately designed as inductively and capacitively acting couplings. 10. Filter according to claims 1 to 5, characterized in that the additional coupling The organs provided for the resonators are designed as coupling slots and / or as perforated diaphragms. 11. Filter according to claim 6, characterized in that with symmetrical bridging individual Filter sections the additional couplings (2/7, 3/6, 8/13, 9/12) and the innermost coupling (4/5, 10/11) of the respective filter section in the coupling type are in the same direction (capacitive or inductive), while for the other couplings (1/2, 2/3, 3/4, 5/6, 6/7, 7/8, 8/9, 9/10, U / 12,12 / 13,13 / 14) the this opposing type of coupling (inductive or kaoacitive) is used (FIG. 5).